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MEN1, GHRH and gigantismV S Nadhamuni and others
GHRH secretion from a pancreatic neuroendocrine tumor causing gigantism in a patient with MEN1
Vinaya Srirangam Nadhamuni 1, Donato Iacovazzo1, Jane Evanson2, Anju Sahdev2, Jacqueline Trouillas3, Lorraine McAndrew2, Tom R Kurzawinski4, David Bryant5, Khalid Hussain6, Satya Bhattacharya2 and Márta Korbonits 1
1Department of Endocrinology, Barts and the London School of Medicine and Dentistry, William Harvey Research Institute, Queen Mary University of London, London, UK, 2St. Bartholomew’s Hospital, Barts and the London NHS Trust, London, UK, 3Department of Pathology, Groupement Hospitalier Est, Hospices Civils de Lyon, Bron, France, 4Division of Endocrine Surgery, University College Hospital, London, UK, 5Sunderland Royal Hospital, South Tyneside and Sunderland NHS Foundation Trust, South Shields, Tyne and Wear, UK , and 6Division of Endocrinology, Sidra Medicine, Doha, Ad Dawhah, Qatar
Summary
A male patient with a germline mutation in MEN1 presented at the age of 18 with classical features of gigantism. Previously, he had undergone resection of an insulin-secreting pancreatic neuroendocrine tumour (pNET) at the age of 10 years and had subtotal parathyroidectomy due to primary hyperparathyroidism at the age of 15 years. He was found to have�significantly�elevated�serum�IGF-1,�GH,�GHRH�and�calcitonin�levels.�Pituitary�MRI�showed�an�overall�bulky�gland�with�a 3 mm hypoechoic area. Abdominal MRI showed a 27 mm mass in the head of the pancreas and a 6 mm lesion in the tail. Lanreotide-Autogel 120 mg/month reduced GHRH by 45% and IGF-1 by 20%. Following pancreaticoduodenectomy, four NETs�were�identified�with�positive�GHRH�and�calcitonin�staining�and�Ki-67�index�of�2%�in�the�largest�lesion.�The�pancreas�tail lesion was not removed. Post-operatively, GHRH and calcitonin levels were undetectable, IGF-1 levels normalised and GH suppressed normally on glucose challenge. Post-operative fasting glucose and HbA1c levels have remained normal at the last check-up. While adolescent-onset cases of GHRH-secreting pNETs have been described, to the best of our knowledge,�this�is�the�first�reported�case�of�ectopic�GHRH�in�a�paediatric�setting�leading�to�gigantism�in�a�patient�with�MEN1. Our case highlights the importance of distinguishing between pituitary and ectopic causes of gigantism, especially in�the�setting�of�MEN1,�where�paediatric�somatotroph�adenomas�causing�gigantism�are�extremely�rare.
-20-0208ID: 20-0208
Correspondence should be addressed to M Korbonits Email [email protected]
Learning points
• It is important to diagnose gigantism and its underlying cause (pituitary vs ectopic) early in order to prevent further growth and avoid unnecessary pituitary surgery. The most common primary tumour sites in ectopic acromegaly include the lung (53%) and the pancreas (34%) (1): 76% of patients with a pNET secreting GHRH showed a MEN1 mutation (1).
• Plasma GHRH testing is readily available in international laboratories and can be a useful diagnostic tool in distinguishing between pituitary acromegaly mediated by GH and ectopic acromegaly mediated by GHRH. Positive GHRH�immunostaining�in�the�NET�tissue�confirms�the�diagnosis.�
• Distinguishing between pituitary (somatotroph) hyperplasia secondary to ectopic GHRH and pituitary adenoma is�difficult�and�requires�specialist�neuroradiology�input�and�consideration,�especially�in�the�MEN1�setting.�It�is�important to note that the vast majority of GHRH-secreting tumours (lung, pancreas, phaeochromocytoma) are expected�to�be�visible�on�cross-sectional�imaging�(median�diameter�55�mm)�(1). Therefore, we suggest that a chest X-ray and an abdominal ultrasound checking the adrenal glands and the pancreas should be included in the routine work-up of newly diagnosed acromegaly patients.
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Introduction
Gigantism is a rare condition which is due, in most cases, to excess growth hormone (GH) in childhood leading to accelerated growth and increased height (as the epiphyseal plates are not fused). Pituitary gigantism and acromegaly are on a continuum with most patients with gigantism also showing acromegalic features such as coarse facial features or pronounced growth of hands and feet.
The majority of cases of gigantism/acromegaly are secondary to GH-secreting pituitary adenomas, which may be syndromic or non-syndromic. Syndromic causes include Carney complex, multiple endocrine neoplasia types 1 and 4, and the paraganglioma, phaeochromocytoma and pituitary adenoma association (3PAs). Non-syndromic causes include familial isolated pituitary adenoma secondary to germline AIP mutations or duplication of GPR101, causing X-linked acrogigantism (2, 3). However, gigantism can be a sign of other conditions as well (4, 5, 6).
GH excess due to a growth hormone-releasing hormone (GHRH)-secreting tumour accounts for less than 1% of cases of acromegaly (1, 7). We describe here a rare case of gigantism due to childhood-onset GH excess secondary to GHRH secreted by a pancreatic neuroendocrine tumour (pNET) in a patient with MEN1. This is the first case of paediatric-onset gigantism from ectopic GHRH in a MEN1 setting to be reported in the literature, to the best of our knowledge.
Case presentation
An 18-year-old Caucasian male was referred for evaluation of accelerated growth velocity (Fig. 1).
His medical history started at the age of 7 years, when he experienced increasingly frequent and recurrent tonic–clonic seizures. These were found to be related to hyperinsulinaemic hypoglycaemia (lowest glucose level: 1.5 mmol/L). MRI revealed a 1cm lesion in the pancreatic neck. At the age of 10, the patient underwent enucleation of the tumour. Histopathology revealed a well-differentiated NET strongly positive for proinsulin and insulin with a few scattered cells positive for glucagon, somatostatin and calcitonin. He developed multiple post-operative complications including abdominal haemorrhage, pancreatitis, septic shock, renal failure and encephalopathy, but he completely recovered.
At the age of 11, genetic testing revealed a heterozygous germline mutation in the MEN1 gene (c.249_252delGTCT, p.I85Sfs). His father carries the same mutation and has hyperparathyroidism as the only clinical manifestation.
Several family members on his father’s side are under endocrine care for MEN1 syndrome.
At the age of 14 years, he was diagnosed with primary hyperparathyroidism secondary to parathyroid hyperplasia. He underwent a subtotal parathyroidectomy (three of four glands removed, right upper parathyroid left in place) and transcervical thymectomy.
At first evaluation at the adult endocrine clinic at the age 18, he was noted to be 193.5 cm tall (>97th percentile, mid-parental height 175 cm). He was noted to have long and thin hands, UK shoe size 12 (increased by 2 sizes in the 2 years prior to evaluation), dorsal kyphosis and hyperhidrosis. He did not complain of headaches, visual problems or sleeping problems, and went through puberty normally. His skin was normal. His face did not show prominence of eyebrows and chin or enlargement of tongue. Stretch marks on both shoulders and horizontally on the back were noted, possibly secondary to accelerated growth.
Investigations
At the age of 18, IGF-1 was 2xULN (970 µg/L, normal range 247–481, Fig. 2). Random morning GH levels were elevated at 39 µg/L with GH nadir during the oral glucose tolerance test (OGTT) 1.7 µg/L (<1). He had normal serum prolactin (213 mU/L, 0–324), TSH (1.12 mU/L, 0.3–4) and FT4 levels (15.7 pmol/L, 10.5–24.5). Fasting plasma GHRH was significantly elevated at 327 ng/L (<60, Biomnis, Lyon, France). Chromogranin A and gut peptide levels were normal (gastrin 5 pmol/L (<50), glucagon 13 pmol/L (<50), VIP 4 pmol/L (<30), pancreatic polypeptide 43 pmol/L (<300), chromogranin A 44 pmol/L (<60) and somatostatin 54 pmol/L (<150). Calcitonin levels were noted to be elevated at presentation at 82 ng/L (<0.8–4). No thyroid parenchymal lesions were noted on ultrasound imaging. His corrected calcium was normal at 2.55 mmol/L (2.2–2.6) with normal phosphate 1.19 mmol/L (0.8–1.5) but slightly elevated PTH of 8.4 pmol/l (1.6–6.7) and decreased 25-OH vitamin D levels of 8 nmol/L (>50). His urinary 24-h calcium was increased at 13 mmol/L(2.5–7.5). Bone age of 19 years was noted on hand X-ray (within 2 s.d. from chronological age).
Abdominal MRI revealed two lesions in the pancreatic head and tail, measuring 27 mm (Fig. 3) and 6 mm, respectively (Table 1), in keeping with NETs. A pituitary MRI showed a diffusely enlarged gland and raised the possibility of a 3 mm microadenoma showing slightly reduced enhancement in the right inferolateral aspect of the anterior pituitary (Figs 4A and 5B).
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Treatment
He was initially started on treatment with 120 mg Lanreotide-Autogel monthly (every 28 days) for 6 months with partial biochemical response of a random serum GH 2.21 µg/L, IGF-1 778 µg/L (1.6× ULN) and a 50% drop in GHRH to 180 ng/L (<60). He received vitamin D replacement. Following careful discussion of the various therapeutic options with the multi-disciplinary team and the patient and his family, he underwent a pylorus-sparing pancreatoduodenectomy and cholecystectomy with the removal of the head and neck of the pancreas, including the largest tumour leaving the pancreatic tail (including the 6mm lesion) intact. The operation and the post-operative period was without complications.
Figure 1Patient's�growth�chart�up�to�the�age�of�18�showing�accelerated�growth�velocity.�His�final�height,�193.5�cm,�is�corresponding�to�height�standard�deviation�scores: UK Tanner Whitehouse for chronological age (18 years) +2.83, adjusted for parental height +2.87 and UK Cole: for chronological age (18 years) +2.34, adjusted for parental height +2.38.
Figure 2IGF-1 levels of the patient during the clinical course.
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Histological examination identified four grade 1 and 2 NETs in the pancreas, positive for synaptophysin and chromogranin (Table 1). There was no lymph node invasion. The largest tumour was a well-differentiated NET positive for GHRH, SSTR2 and calcitonin on immunohistochemistry with a Ki-67 index of 2% (Table 1, Fig. 6). The GHRH and SSTR2 expression were strong but focal, with large negative areas and small areas with 50–100% of positive cells. The immunohistological detection of somatostatin, insulin and GH was negative in the four tumours (Table 1).
Post-operatively, GHRH and calcitonin were undetectable with IGF-1 returning into the normal range (264 µg/L) and a nadir GH of 0.5 µg/L on the OGTT. Post-operatively, mild left-sided intrahepatic duct dilatation was noted, which was secondary to a likely benign stricture at the entero-biliary anastomosis. Pituitary MRI showed a reduction in the height of the pituitary gland (Fig. 4C and D).
Outcome and follow-up
Following surgery, over the last 5 years the patient has remained largely asymptomatic. His main problems during follow-up had been related to recurrent kidney stones and he underwent successful extracorporeal shock wave lithotripsy to a right lower pole renal calculus. He was started on cinacalcet 30 mg, which was increased to 30 mg twice a day, and vitamin D3 10 000 units weekly were continued. The most recent corrected calcium is 2.24 mmol/L (2.2–2.6), phosphate 1.08 mmol/L (0.8–1.5), PTH 10.4 pmol/L (1.6–6.9) and 25-OH vitamin D3 73 nmol/L. Urinary 24 h calcium output is 11.8 mmol/day (2.5–7.5).
Figure 3MRI abdomen at presentation with an arrow indicating the larger (27 mm) lesion in the head of the pancreas in keeping with a NET. Ta
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Post-operative fasting glucose levels 5.3 mmol/L (4–5.4) and HbA1c (27 mmol/L) (20–41) have remained normal at the last check-up. The lesions in the tail of his pancreas, pituitary as well as a hyperplastic right lower parathyroid gland are stable in size over the last 5 years. A full summary of his latest follow-up and surveillance regimen with comparison to present clinical guidelines (8) is provided in Table 2.
Discussion
We report the case of a now 24-year-old gentleman with gigantism, multiple pNETs, a possible pituitary microadenoma and parathyroid tumour and hyperplasia due to a germline mutation in MEN1. He had developed gigantism due to excess of GH and IGF-1 during childhood secondary to the secretion of GHRH by a pNET. Although this is the first reported case of gigantism in a paediatric setting due to ectopic GHRH in a patient with MEN1 syndrome, ectopic GHRH secretion in an adolescent patient with MEN1 was included in a previous case series (9) and personal communication with Francoise Borson-Chazot, France who confirmed gigantism in that case).
Early detection of growth hormone excess is important as many of the effects of growth hormone cannot be reversed with treatment which aims to limit any further consequences (i.e. prevent further growth in the case of gigantism).
Ectopic secretion of GHRH is a rare cause of GH excess, accounting for less than 1% of all cases of acromegaly (1, 7). Ectopic sources mainly include NETs, usually of pancreatic (34%) or bronchial origin (53%) (1, 9). Ectopic GHRH secretion by phaeochromocytomas has also been reported (4%) (1, 10, 11, 12). However, while ectopic acromegaly is an uncommon entity, its diagnosis is important for two main reasons: (i) avoidance of unnecessary pituitary surgery (13) and institution of appropriate management of the non-pituitary NET and (ii) screening for associated syndromes such as MEN1.
GHRH-secreting pNETs in the setting of MEN1 are well described (9, 14, 15, 16, 17), with one series showing 76% of patients with a pNET secreting GHRH having MEN1 mutations (1). Determining whether acromegaly is of pituitary or non-pituitary origin can be difficult but is of paramount importance, as unnecessary pituitary surgery and consequent potential hypopituitarism should be avoided in patients with ectopic acromegaly. It is important to note that the vast majority of GHRH-secreting tumours (lung, pancreas, phaeoechromocytoma) are expected to be visible on cross-sectional imaging (median diameter 55 mm) (1). Therefore, we suggest that a chest X-ray and an abdominal ultrasound checking the adrenal glands and the pancreas should be included in the routine work-up of newly diagnosed acromegaly patients. It is worth remembering that an elevated fasting plasma GHRH is specific for ectopic GHRH release (1, 13) and highly useful in this diagnostic setting and several assays are now available. Monitoring GHRH following treatment can help identify the persistence or recurrence of disease
Figure 4Coronal MRI pre- (A,B) and post-pancreatic (C,D) surgery showing shrinkage of the pituitary gland following surgery.
Figure 5MRI with pituitary microadenoma (arrow), (A–B) before pancreas surgery (A: T1-weighted image, B: T2-weighted image) and (C–D) 4 years after pancreas surgery (C: post-gadolinium T1, D: T2).
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(1). In our patient’s case, GHRH was undetectable after a large pancreatic resection and the removal of a pNET secreting GHRH. GHRH positive cells can be scattered or located in sheets, especially in well-differentiated cells; therefore, a systematic GHRH immunostaining is needed in all tumour fragments to prove the pancreatic origin of the GHRH ectopic secretion.
With respect to imaging, pituitary (somatotroph) hyperplasia has been observed secondary to ectopic GHRH release (1, 7, 13, 18), which could be misinterpreted as a pituitary macroadenoma (1). Indeed, in many instances from the literature, an ectopic source for acromegaly was considered only after unnecessary pituitary surgery due to misinterpretation of pituitary hyperplasia as adenoma in the context of clinical and acromegaly and elevated GH and IGF-1 levels (7, 9, 13). Interpretation of pituitary imaging by an experienced neuro-radiologist may help avoid
this situation. In our patient’s case, while the pituitary gland was clearly bulky (Figs 4 and 5), a possible pituitary microadenoma was also described. Due to the large lesion in the head of the pancreas and the elevated GHRH, we opted for pancreatic surgery initially, but could not be sure at the time if acromegaly would fully resolve after surgery. The pituitary lesion has remained stable, and might well represent a small non-functioning microadenoma, similarly to those observed in a surveillance study of MEN1 patients (19).
We found significantly elevated calcitonin levels in this patient. Calcitonin expression on immunohistochemistry was found in 11% of cases in a large study screening 229 pNETs (20). It is unclear how often calcitonin-secreting pNETs occur in the setting of MEN1, although previous cases have been reported (21, 22, 23, 24), including a case with both GHRH and calcitonin secretion, similar to our case.
Figure 6Representative images of the histopathology of the largest pNET. H&E, 4× (A) and 20× (B) power and immunohistochemistry for calcitonin (C), GHRH (D), Ki-67 (E), chromogranin A (F) and SSTR2 (G) (20×).
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To date, our patient has developed multiple NETs in the pancreas, six in total, with the removal of five through two surgical procedures. The possibility of total pancreatectomy was discussed with the patient as an option for managing the existing lesions as well as prophylaxis against any future lesions, but with the inevitable consequence of insulin-dependent diabetes. The patient decided against this option, given the need for life-long insulin treatment post-operatively. We continue to monitor the NET in the tail of the pancreas through biochemical assessment and surveillance imaging.
Timely diagnosis of MEN1 is important to improve disease outcomes and survival in patients as well as affected family members (25). A recent cohort study of Dutch MEN1 patients investigating the lag time between diagnosis of MEN1 in index patients and their family members (non-index patients) found that 10 patients (4% of non-index cases) died because of a MEN1-related cause that developed during or before the lag time (pre-diagnosis) (26). Patients should be managed by a multi-disciplinary team of relevant specialists experienced in the diagnosis and treatment of patients with endocrine tumours (8) in order to facilitate appropriate genetic screening of family members as well as ensure appropriate surveillance protocols are carried out in affected patients.
Declaration of interestThe� authors� declare� that� there� is� no� conflict� of� interest� that� could� be�perceived as prejudicing the impartiality of the research reported.
FundingVSN is an NIHR academic clinical fellow and received support from Cancer Research UK and the Pathological Society. MK’s work on pituitary adenomas was supported by the Medical Research Council, the Rosetrees Trust and Barts Charity.
Patient consentWritten informed consent for publication of the clinical details and images was obtained from the patient.
Author contribution statementVSN reviewed the case and drafted the manuscript. The other authors cared for the patient. All authors reviewed and edited the manuscript.
References 1 Borson-Chazot F, Garby L, Raverot G, Claustrat F, Raverot V, Sassolas G.
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Table 2 Summary of clinical practice recommendations for surveillance for MEN1 patients with results of investigations for our patient from last outpatient review. Adapted from Thakker et al. (2012) (8).
Organ system Recommendation from Thakker et al. (2012) (8)Findings from the investigation at last outpatient review
Parathyroid Biochemical: Annual assessment of plasma calcium and PTH concentrations
PTH elevated at 10.4 pmol/L (reference range:�1.6–6.9)�with�normal�corrected�calcium levels
Imaging: Not suggested Ultrasound: residual hyperplastic right upper parathyroid gland with a stable enlargement (maximum�diameter�of�14�mm)�
Pancreatic NET Biochemical: Annual plasma evaluation of fasting GIT hormone�profile�including�gastrin,�glucagon,�VIP,�pancreatic polypeptide, chromogranin A, insulin and fasting glucose recommended
All normal, insulin was not tested
Imaging: Annual pancreatic and duodenal visualisation with MRI/CT/endoscopic ultrasound
Lesion in the tail of the pancreas remained stable (measuring 6 mm)
Pituitary Biochemical: Annual assessment of plasma prolactin and IGF-1
IGF-1, GH serum, FSH, LH, serum oestradiol and prolactin levels normal
Imaging: MRI every 3–5 years 3 mm focal lesion in the right dorsal aspect of pituitary tissue (microadenoma)
Thymic, bronchopulmonary and gastric NET
Imaging: CT/ MRI of the chest every 1–2 yearsrecommended for thymic and bronchopulmonary carcinoid tumours.Gastroscopy with biopsy every 3 years in patients with hypergastrinaemia
Normal residual thymic tissue and no focal lung lesion. Gastroscopy not performed as patient has no symptoms, normal gastrin levels and had removal of the duodenum
Adrenal tumours Biochemical: Evaluation restricted to those with clinical features or tumours more than 1cm in size
Not applicable as no relevant clinical features or focal lesions in the adrenal glands
Imaging: CT/ MRI of the abdomen every 3 years No focal lesions in the adrenal gland
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Received in final form 5 April 2021Accepted 13 May 2021
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